Halogen egg half-cutting and discharging device
By designing a device for halving and feeding braised eggs, an automated halving and flipping mechanism using fine wires and rotating blocks is achieved, solving the problems of low efficiency and hygiene associated with manual operation, thus improving efficiency and reducing costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WENZHOU RUICHI MACHINERY CO LTD
- Filing Date
- 2025-04-30
- Publication Date
- 2026-06-26
AI Technical Summary
In existing technologies, the halving and packaging of braised eggs mainly relies on manual operation, which is inefficient, labor-intensive, and difficult to ensure hygiene.
A device for halving and feeding braised eggs was designed. It utilizes a multi-row, multi-column material chamber, filaments, and a rotating block structure. The filaments are driven by servo motors and rotary motors to halve and flip the braised eggs. Combined with a sealing plate to control the feeding of the braised eggs, the device achieves automated operation.
This improved the efficiency of cutting and feeding marinated eggs, reduced labor costs, and ensured hygiene during the packaging process.
Smart Images

Figure CN224407760U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of food packaging equipment, specifically to a device for cutting and feeding braised eggs in half. Background Technology
[0002] Consumers, especially young children, often only eat a portion of braised eggs at a time, leading to waste. Additionally, whole braised eggs don't absorb the flavor well, so there's a demand for them to be cut in half before packaging. However, with current technology, cutting braised eggs in half for packaging is generally done manually, which is inefficient, physically demanding for workers, and most importantly, cannot guarantee hygiene. Utility Model Content
[0003] To address the aforementioned problems, the purpose of this utility model is to provide a device for cutting and dispensing braised eggs in half, thereby improving efficiency, reducing labor costs, and ensuring hygiene.
[0004] To achieve the above objectives, this utility model provides the following technical solution: a device for cutting and feeding halved braised eggs, comprising multiple rows and columns of material cavities for placing braised eggs. Each row of material cavities has a set of fine wires above it. Each set of fine wires includes a first fine wire for cutting the braised eggs in half and a second fine wire for turning the already cut braised eggs over. The first and second fine wires are aligned front to back. The two ends of the first and second fine wires are connected to a rotating block. The rotating block is rotatably mounted on a lifting plate. The lifting plate is set to move up and down and moves back and forth relative to the material cavities. A through-hole for turning and displacing fine wires is provided between adjacent material cavities in each row of material cavities. A sealing plate that can be opened or closed is provided at the bottom of the material cavities.
[0005] The second filament is set in two sections, one at the front and one at the back.
[0006] The sealing plate is provided with through holes that correspond one-to-one with and are adapted to the material chamber. The sealing plate is moved by the sealing plate cylinder. When the through hole is aligned with the bottom of the material chamber, the material can fall out of the material chamber.
[0007] The lifting plate can move up and down on a fixed frame and is controlled and driven by a servo motor. A rotary motor is installed on the lifting plate. The rotary motor synchronously drives multiple transmission rods through gears. Each transmission rod drives a set of rotating blocks with fine wires.
[0008] Each drive rod has a synchronous pulley at both ends, which drives the rotating block to rotate via a synchronous belt.
[0009] The operation process of this utility model is as follows: After the braised egg is manually or automatically placed into the material chamber, the bottom of the braised egg is supported by the sealing plate. The material chamber moves to below the lifting plate, and the lifting plate moves downward, driving the thin wires downward into the material chamber to cut the braised egg in half. At this time, the first and second thin wires are aligned front to back in the vertical direction, with the first thin wire at the bottom. After the braised egg is cut in half, the lifting plate moves slightly upward, so that the first and second thin wires are both within the thin wire flipping clearance hole area. Then, the rotating block drives the first and second thin wires to flip 90 degrees, so that the first and second thin wires are aligned front to back in the horizontal direction. During the 90-degree flipping process of the first and second thin wires, the first and second thin wires will simultaneously push the halved braised egg 90 degrees. The egg flips 180 degrees, causing the left half to flip downwards and be supported by the sealing plate, while the right half flips upwards and is supported by the first and second filaments. At this point, the sealing plate moves, aligning its through-hole with the bottom of the material chamber. The left half of the egg, due to gravity, falls out of the material chamber and enters the moving stretch membrane bubble for transport. Next, the rotating block drives the first and second filaments to flip 180 degrees, pushing the right half of the egg downwards 180 degrees. Finally, the right half of the egg also falls out of the material chamber and enters the moving stretch membrane bubble for transport. After these actions are completed, the filaments return to their original position, with the first and second filaments aligned vertically and the first filament at the bottom. Then, the lifting plate returns to its original position, and the material chamber also returns to its original position. This cycle repeats automatically, halving the egg and discharging it separately, greatly improving efficiency, reducing labor costs, and ensuring hygiene. Attached Figure Description
[0010] Figure 1 is a perspective view of a specific embodiment of the present utility model;
[0011] Figure 2 is a cross-sectional view of a specific embodiment of the present invention;
[0012] Figure 3 is an enlarged view of A in Figure 2;
[0013] Figure 4 is a partial cross-sectional view of a specific embodiment of the present invention;
[0014] Figure 5 is a partial view of the installation of the transmission rod in a specific embodiment of this utility model.
[0015] In the diagram, 1 is the material chamber; 2 is the filament; 21 is the first filament; 22 is the second filament; 3 is the rotating block; 4 is the support plate; 41 is the cutting groove; 42 is the filament flipping clearance hole; 5 is the fixing frame; 6 is the lifting plate; 7 is the transmission rod; 8 is the transmission gear; 9 is the rotary motor; 11 is the sealing plate; 12 is the sealing plate cylinder; 20 is the synchronous belt; 30 is the internal threaded sleeve; 40 is the screw; 50 is the servo motor; 60 is the insertion plate; 70 is the moving cylinder; 80 is the material frame; and 90 is the clearance groove. Detailed Implementation
[0016] The present invention will be specifically described below through embodiments, which are only used to further illustrate the present invention and should not be construed as limiting the scope of protection of the present invention.
[0017] As shown in Figures 1-5, this embodiment discloses a device for cutting and feeding halved braised eggs, including a tray 4. The tray 4 is provided with multiple rows and columns of material chambers 1 for placing braised eggs. Each row of material chambers 1 has a vertically penetrating cutting groove 41 in the middle. A set of thin filaments 2 is provided above each row of material chambers 1. Each set of thin filaments 2 includes a first thin filament 21 for cutting the braised eggs in half and a second thin filament 22 for pushing the halved braised eggs to flip. The first and second thin filaments are aligned front to back. There are two second thin filaments 22, one in front and one behind, so that the two second thin filaments 22 can more conveniently support the cut braised eggs. The diameter of the thin filaments is 0.12mm. The first and second filaments are connected to the rotating block 3 at both ends. The rotating block 31 is rotatably mounted on the lifting plate 6. The lifting plate 6 is movable up and down in the fixed frame 5. The fixed frame 5 is fixedly installed. The support plate 4 is pushed back and forth by the moving cylinder 70. There is a through filament flipping clearance hole 42 between adjacent material chambers of each row of material chambers 1. The bottom of the material chamber 1 is provided with a sealing plate 11 that can be opened or closed.
[0018] The sealing plate 11 is provided with through holes that correspond one-to-one with and are adapted to the material chamber 1. The sealing plate 11 is moved by the sealing plate cylinder 12. When the through hole is aligned with the bottom of the material chamber 1, the material can fall out of the material chamber. This structure is reliable and stable, and can easily control the opening and closing of the bottom of all material chambers 1.
[0019] The lifting plate 6 is movable up and down on the fixed frame 5 and is controlled and driven by the servo motor 50. A rotary motor 9 is installed on the lifting plate 6. The rotary motor 9 synchronously drives multiple transmission rods 7 through gears. Each transmission rod 7 corresponds to a set of rotating blocks 3 with fine wires. Each transmission rod 7 has synchronous pulleys at both ends, which drive the rotating blocks 3 to rotate via a synchronous belt. Specifically, the four corners of the lifting plate 6 slide on vertical guide rods to improve lifting stability. The transmission rods 7 are rotatably mounted on the lifting plate 6, as shown in Figure 5. One end of each transmission rod 7 has a transmission gear 8. The rotary motor 9 is installed on the lifting plate 6, and a drive gear is connected to the output shaft of the rotary motor 9. The drive gear meshes with the transmission gear 8, and the transmission gears 8 mesh with each other through synchronous gears. One end of each transmission rod 7 is equipped with a first synchronous pulley, and the rotating block 3 is also equipped with a second synchronous pulley. The first and second synchronous pulleys are connected by a synchronous belt 20. Thus, the rotary motor 9... The transmission rod 7 is driven to rotate, and the transmission rod 7 controls the rotation of the rotating block 3 through the synchronous belt 20, so that the rotary motor 9 drives the rotation of the rotating block 3.
[0020] A rotatable internal threaded sleeve 30 is also installed on the fixed frame 5. A screw 40 is connected to the lifting plate 6. The screw 40 is threadedly connected to the internal threaded sleeve 30. The outer wall of the internal threaded sleeve 30 is fitted with a lifting synchronous pulley. A servo motor 50 is installed on the fixed frame. A main synchronous pulley is configured on the output shaft of the servo motor 50. The main synchronous pulley is connected to the lifting synchronous pulley through a lifting belt. In this way, the servo motor 50 can drive the rotation of the internal threaded sleeve 30 and drive the lifting plate 6 to rise and fall through the screw 40, thereby controlling the rise and fall of the three thin wires 2.
[0021] A plate 60 with an inner cavity is installed on the lifting plate 6. The rotating shaft is rotatably installed at the end of the plate 60 through a bearing. The first synchronous pulley, the second synchronous pulley, and the synchronous belt 20 are placed in the inner cavity of the plate 60. The plate 60 makes the rotation of the rotating block 3 more stable and reliable. At the same time, a relief groove 90 is provided on the support plate 4 for the end of the plate 60 to be inserted. In this way, the filament 2 between the rotating blocks 3 can be accurately inserted into the material cavity 1 to cut or flip the braised eggs in the material cavity 1.
[0022] The tray 4 is mounted on a guide rail and is driven by a moving cylinder 70. The tray 4 can be moved to below or away from the lifting plate 6 by the moving cylinder 70, so that the top of the tray 4 is empty and the braised egg material can be conveniently placed in the material cavity 1 of the tray 4.
[0023] During feeding, the eggs can be placed in a material frame 80. The material frame 80 has outlets that correspond one-to-one with the material chambers. The materials can be manually or mechanically fed into the material chambers. Of course, the material frame can be made retractable to improve the feeding efficiency.
[0024] The operation process of this utility model is as follows: After the braised egg is manually or automatically placed into the material chamber 1, the bottom of the braised egg is supported by the sealing plate. The material chamber moves to the bottom of the lifting plate, and the lifting plate moves downward, driving the thin wires downward through the cutting groove 41 into the material chamber to cut the braised egg in half. At this time, the first and second thin wires are aligned front and back in the vertical direction, with the first thin wire at the bottom. After the braised egg is cut in half, the lifting plate moves slightly upward, so that the first and second thin wires are both within the thin wire flipping clearance hole area. Then, the rotating block drives the first and second thin wires to flip 90 degrees, so that the first and second thin wires are aligned front and back in the horizontal direction. During the 90-degree flipping process of the first and second thin wires, the first and second thin wires will simultaneously push the halved braised egg 90 degrees. The egg flips 180 degrees, causing the left half to flip downwards and be supported by the sealing plate, while the right half flips upwards and is supported by the first and second filaments. The sealing plate then moves, aligning its through-hole with the bottom of the material chamber. The left half of the egg, due to gravity, falls out of the material chamber and enters the moving stretch membrane bubble for transport. The sealing plate returns to its original position. Next, the rotating block drives the first and second filaments to flip 180 degrees, pushing the right half of the egg downwards 180 degrees. Finally, the right half of the egg also falls out of the material chamber and enters the moving stretch membrane bubble for transport. After completing these actions, the filaments return to their original position, with the first and second filaments aligned vertically, the first filament at the bottom. Then, the lifting plate returns to its original position, and the support plate also returns to its original position. This cycle repeats automatically, halving the egg and discharging it separately, greatly improving efficiency, reducing labor costs, and ensuring hygiene.
Claims
1. A device for halving and dispensing braised eggs, comprising multiple rows and columns of material chambers for placing braised eggs, characterized in that: Above each row of material chambers is a set of fine wires. Each set of fine wires includes a first fine wire that cuts the braised egg in half and a second fine wire that pushes the already cut braised egg to flip over. The first and second fine wires are aligned front to back. The two ends of the first and second fine wires are connected to a rotating block. The rotating block is rotatably mounted on a lifting plate. The lifting plate is set to move up and down and moves back and forth relative to the material chambers. There are through holes for the fine wires to flip and make room between adjacent material chambers in each row. The bottom of the material chamber is equipped with a sealing plate that can be opened or closed.
2. The device for halving and feeding braised eggs according to claim 1, characterized in that: The second filament is set in two sections, one at the front and one at the back.
3. The device for halving and feeding braised eggs according to claim 1 or 2, characterized in that: The sealing plate is provided with through holes that correspond one-to-one with and are adapted to the material chamber. The sealing plate is moved by the sealing plate cylinder. When the through hole is aligned with the bottom of the material chamber, the material can fall out of the material chamber.
4. The device for halving and feeding braised eggs according to claim 1 or 2, characterized in that: The lifting plate can move up and down on a fixed frame and is controlled and driven by a servo motor. A rotary motor is installed on the lifting plate. The rotary motor synchronously drives multiple transmission rods through gears. Each transmission rod drives a set of rotating blocks with fine wires.
5. The device for halving and feeding braised eggs according to claim 4, characterized in that: Each drive rod has a synchronous pulley at both ends, which drives the rotating block to rotate via a synchronous belt.